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Main Authors: Xiao‐Na Sun, Ao Liu, Kaidi Xu, Zhe Zheng, Kai Xu, Ming Dong, Bo Ding, Jian Li, Zhi‐Yuan Zhang, Chunju Li
Format: Artículo Open Access
Published: Wiley 2024
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Online Access:https://onlinelibrary.wiley.com/doi/10.1002/agt2.607
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author Xiao‐Na Sun
Ao Liu
Kaidi Xu
Zhe Zheng
Kai Xu
Ming Dong
Bo Ding
Jian Li
Zhi‐Yuan Zhang
Chunju Li
author_facet Xiao‐Na Sun
Ao Liu
Kaidi Xu
Zhe Zheng
Kai Xu
Ming Dong
Bo Ding
Jian Li
Zhi‐Yuan Zhang
Chunju Li
Xiao‐Na Sun
Ao Liu
Kaidi Xu
Zhe Zheng
Kai Xu
Ming Dong
Bo Ding
Jian Li
Zhi‐Yuan Zhang
Chunju Li
collection Wiley Open Access
contents Low‐entropy‐penalty synthesis of giant macrocycles for good self‐assembly and emission enhancement Xiao‐Na Sun Ao Liu Kaidi Xu Zhe Zheng Kai Xu Ming Dong Bo Ding Jian Li Zhi‐Yuan Zhang Chunju Li Aggregate AbstractMacrocycles are key tools for molecular recognition and self‐assembly. However, traditionally prevalent macrocyclic compounds exhibit specific cavities with diameters usually less than 1 nm, limiting their range of applications in supramolecular chemistry. The efficient synthesis of giant macrocycles remains a significant challenge because an increase in the monomer number results in cyclization‐entropy loss. In this study, we developed a low‐entropy‐penalty synthesis strategy for producing giant macrocycles in high yields. In this process, long and rigid monomers possessing two reaction modules were condensed with paraformaldehyde via Friedel–Crafts reaction. A series of giant macrocycles with cavities of sizes ranging from 2.0 to 4.7 nm were successfully synthesized with cyclization yields of up to 72%. Experimental results and theoretical calculations revealed that extending the monomer length rather than increasing the monomer numbers could notably reduce the cyclization‐entropy penalty and avoid configuration twists, thereby favoring the formation of giant macrocycles with large cavities. Significantly, the excellent self‐assembly capacity of these giant macrocycles promoted their assembly into organogels. The xerogels exhibited enhanced photoluminescence quantum efficiencies of up to 83.1%. Mechanism investigation revealed the excellent assembly capacity originated from the abundant π–π interactions sites of the giant macrocycles. The outstanding emission enhancement resulted from the restricted nonradiative decay processes of rotation/vibration and improved radiative decay process of fluorescence. This study provides an effective and general method for achieving giant macrocycles, thereby expanding the supramolecular toolbox for host–guest chemistry and assembly applications. Moreover, the intriguing assembly and photophysical properties demonstrate the feasibility of developing novel and unique properties by expanding the macrocycle size. 10.1002/agt2.607 http://creativecommons.org/licenses/by/4.0/
doi_str_mv 10.1002/agt2.607
format Artículo Open Access
id wiley_oa_10_1002_agt2_607
institution Wiley Open Access
license_str_mv http://creativecommons.org/licenses/by/4.0/
publishDate 2024
publisher Wiley
record_format wiley_oa
spellingShingle Low‐entropy‐penalty synthesis of giant macrocycles for good self‐assembly and emission enhancement
Xiao‐Na Sun
Ao Liu
Kaidi Xu
Zhe Zheng
Kai Xu
Ming Dong
Bo Ding
Jian Li
Zhi‐Yuan Zhang
Chunju Li
Aggregate
Low‐entropy‐penalty synthesis of giant macrocycles for good self‐assembly and emission enhancement Xiao‐Na Sun Ao Liu Kaidi Xu Zhe Zheng Kai Xu Ming Dong Bo Ding Jian Li Zhi‐Yuan Zhang Chunju Li Aggregate AbstractMacrocycles are key tools for molecular recognition and self‐assembly. However, traditionally prevalent macrocyclic compounds exhibit specific cavities with diameters usually less than 1 nm, limiting their range of applications in supramolecular chemistry. The efficient synthesis of giant macrocycles remains a significant challenge because an increase in the monomer number results in cyclization‐entropy loss. In this study, we developed a low‐entropy‐penalty synthesis strategy for producing giant macrocycles in high yields. In this process, long and rigid monomers possessing two reaction modules were condensed with paraformaldehyde via Friedel–Crafts reaction. A series of giant macrocycles with cavities of sizes ranging from 2.0 to 4.7 nm were successfully synthesized with cyclization yields of up to 72%. Experimental results and theoretical calculations revealed that extending the monomer length rather than increasing the monomer numbers could notably reduce the cyclization‐entropy penalty and avoid configuration twists, thereby favoring the formation of giant macrocycles with large cavities. Significantly, the excellent self‐assembly capacity of these giant macrocycles promoted their assembly into organogels. The xerogels exhibited enhanced photoluminescence quantum efficiencies of up to 83.1%. Mechanism investigation revealed the excellent assembly capacity originated from the abundant π–π interactions sites of the giant macrocycles. The outstanding emission enhancement resulted from the restricted nonradiative decay processes of rotation/vibration and improved radiative decay process of fluorescence. This study provides an effective and general method for achieving giant macrocycles, thereby expanding the supramolecular toolbox for host–guest chemistry and assembly applications. Moreover, the intriguing assembly and photophysical properties demonstrate the feasibility of developing novel and unique properties by expanding the macrocycle size. 10.1002/agt2.607 http://creativecommons.org/licenses/by/4.0/
title Low‐entropy‐penalty synthesis of giant macrocycles for good self‐assembly and emission enhancement
topic Aggregate
url https://onlinelibrary.wiley.com/doi/10.1002/agt2.607